Similarity and difference in the mechanisms of neonatally induced tolerance and cyclophosphamide-induced tolerance in mice

The mechanisms of cyclophosphamide (CP)-induced tolerance were investigated by comparing with those of neonatally induced tolerance. When C3H/He Slc (C3H; H-2k, Mls-1b) mice were given i.v. either AKR/J Sea (AKR; H-2k, Mls-1a) or (AKR x C3H)F1 (AKC3F1; H-2k, Mls-1a/b) spleen cells and treated i.p. with CP 2 days later, a long-lasting skin allograft tolerance to AKR was induced in each case without any signs of graft-vs-host disease (GVHD). However, typical signs of GVHD were observed in the C3H mice neonatally tolerized with AKR spleen cells, but not in those tolerized with AKC3F1 spleen cells. The expression of TCR V beta 6, which is strongly correlated with the reactivity to Mls-1a Ag (of donor AKR origin), in the periphery was quite different between the two types of tolerant C3H mice. Namely, in the lymph nodes of the C3H mice tolerized with AKR spleen cells and CP, only CD4(+)-V beta 6+, but not CD8(+)-V beta 6+, T cells selectively disappeared, whereas both of them were abrogated in the lymph nodes of the C3H mice neonatally tolerized of AKR. By contrast, in the thymus of the two types of tolerant C3H mice, both CD4+CD8- and CD4-CD8+ single-positive thymocytes expressing TCR V beta 6 were clonally deleted, suggesting that the thymic involvement was the same in each type of tolerance. These results suggest that the preferential disappearance of the CD4(+)-V beta 6+ T cells (of host origin) and the effector T cells of GVHD (of donor origin) occurred only in the periphery of the C3H mice tolerized with AKR spleen cells plus CP and was attributable to the destruction of Ag-stimulated T cells by the CP treatment. In contrast, the intrathymic clonal deletion of immature V beta 6+ T cells was a common mechanism for both of the tolerance induction systems.     

Modulation of F1 cytotoxic potentials by graft-vs-host reaction. Cooperative non-H-2- and H-2D region-gene control of F1 natural resistance to graft-vs-host reaction-associated immunosuppression

Our previous study revealed that in F1 mice raised by crossing C3H/He or AKR/J mice with various H-2-congenic B10-series strains, parental H-2k spleen cells (SC) could not induce the graft-vs-host reaction (GvHR)-associated immunosuppression (GAIS). We also elucidated that a limited number of non-H-2 genes of parental C3H/He or AKR/J mice that had been incorporated into the F1 hybrids determined the F1 resistance to the GAIS, and the present study was done to explore the mechanism implicated in this type of F1 resistance to GAIS. SC from B10.AL mice carrying an rH-2 (K:k I:k S:k D:d) haplotype but not SC from H-2K B10.BR (k k k k) mice induced GAIS of in vitro CTL responses to third-party alloantigens in H-2k/d (C3H/He x B10.D2)F1 recipients mice. Further, SC from H-2k/a (C3H/He x B10.A)F1 mice carrying heterozygous C3H/B10 non-H-2 background but not SC from the same H-2k/a (B10.BR x B10.A)F1 mice but carrying homozygous B10/B10 background induced GAIS in H-2k/d (C3H/He x B10.D2)F1 recipients. Although C3H/He-, B10.BR-, and C3H.OH (d d d k)-SC were incapable of inducing GAIS in (C3H/He x B10.D2)F1 (k/d k/d k/d k/d) recipients, they were all good inducers of GAIS in (C3H.OH x B10.BR)F1 (d/k d/k d/k k/k) recipients. Exactly the same pattern of co-operative non-H-2 AKR and H-2D region-gene control of GAIS was observed on GvHR induced in H-2k/d (AKR/J x B10.D2)F1 recipients. These results suggest that the non-H-2 genes of C3H/He or AKR/J strain inhibit the functional expression of certain antigenic determinant(s) when it is encoded by heterozygous but not homozygous gene(s) linked tightly to H-2D region of k haplotype. Thus, the F1 resistance to GAIS is mediated by immune response of F1 recipients who miss the antigenic determinant(s) against that expressed on cell surface of GvHR-inducing T lymphocytes.     

Interference with cyclophosphamide-induced skin allograft tolerance by cyclosporin A.

In a murine strain combination identical in H-2 Ag but disparate in minor histocompatibility (H) Ag consisting of C3H/He (C3H; H-2k, Mls-1b) mice as recipients and AKR/J (AKR; H-2k, Mls-1a) mice as donors, a permanent skin allograft tolerance can be achieved by the cyclophosphamide (CP)-induced tolerance system that consists of i.v. injection of donor spleen cells (day -2) and i.p. injection of CP 2 days later (day 0). Such permanent take of allografts in CP-induced tolerant mice was interfered with by intramuscular injection of cyclosporin A (CsA) from day -5 to day -1 and their grafts were rejected by 21 days after grafting. Mls-1a-reactive CD4+V beta 6+ T cells in the periphery, as the indicator to follow the kinetics of donor-reactive T cells, increased on day 0 and day 3 in the C3H mice treated with AKR spleen cells alone, whereas they disappeared rapidly from day 0 to day 3 in CP-induced tolerant mice. When CsA capable of interfering with IL-2 production and T cell proliferation was administered before CP treatment in CP-induced tolerance system, the number of CD4+V beta 6+ T cells in periphery did not increase on day 0 and 3, but increased on day 7 in contrast to the decreased number of those in CP-induced tolerant mice. On day 7, MLR against donor cells was decreased in CP-induced tolerant mice, but maintained in CsA-interfered tolerant mice. These result may indicate that the destruction of donor-Ag-stimulated, proliferating T cells by CP is interfered with by CsA, probably because CsA inhibits the proliferation of donor-reactive T cells at the time of CP treatment. Furthermore, these results also implicate that the protocol for immunosuppression with CsA and antimetabolites has to be designed carefully in clinical transplantation.     

Importance of suppressor T cells in cyclophosphamide-induced tolerance to the non-H-2-encoded alloantigens. Is mixed chimerism really required in maintaining a skin allograft tolerance?

Mechanisms of cyclophosphamide (CP)-induced tolerance were studied. When AKR/J Sea (AKR: H-2k) mice were primed i.v. with 5 x 10(7) spleen cells plus 1 x 10(7) bone marrow cells from [C57BL/6 Slc (B6; H-2b) x C3H/He Slc (C3H; H-2k)]F1 (B6C3F1) mice and treated i.p. with 200 mg/kg CP 2 days later, the survival of C3H skin was moderately prolonged, but the survival of either B6 or B6C3F1 skin was not prolonged. By this treatment, however, mixed chimerism of B6C3F1 cells in the AKR mice was not established. When C3H cells were used as the tolerogen, a minimal degree of mixed chimerism associated with profound tolerance to C3H skin was established. Similar results were observed in various donor-recipient combinations. When C3H skin was grafted in the AKR mice 12 wk after the treatment with C3H cells and CP, or B6C3F1 cells and CP, survival of the grafted C3H skin was prolonged remarkably or moderately, respectively, although mixed chimerism was not detectable at the timing of grafting in either of the groups. In this late stage of tolerance, a strong level of tolerogen-specific suppressor cell activity was observed in those tolerant AKR mice. The suppressor activity was mainly attributable to T cells. These results suggest that the role of Ts cells in order to maintain skin tolerance is important in our CP-induced tolerance system, especially in the late stage of tolerance. Moreover, the generation of the Ts cells does not necessarily require the establishment of a long term mixed chimeric state.     

Evidence for differential induction of helper T cell subsets during Trichinella spiralis infection

The H-2-compatible mouse strains, AKR and B10.BR, exhibit disparate responses to infection with the parasitic nematode Trichinella spiralis. The resistant AKR mice expel intestinal adult worms faster than susceptible B10.BR mice. We tested antibody and lymphokine responses in these strains. With respect to antibody responses, the B10.BR mice had 3- to 10-fold more serum IgE and T. spiralis-specific IgG1 and IgA than AKR mice. The B10.BR mice also had greater numbers of IgG and IgA plaque-forming cells than AKR mice. In contrast, AKR mice produced T. spiralis-specific IgG2a, whereas the B10.BR mice did not. The antibody response kinetics of these strains were similar. We also analyzed lymphokine secretion after restimulating lymphocytes in vitro with T. spiralis Ag. The AKR mesenteric lymph node cells produced more IFN-gamma and less IL-4 than the B10.BR mesenteric lymph node cells. The B10.BR splenocytes produced more IL-4 than the AKR splenocytes, although splenocyte IFN-gamma production was not different. The kinetics of IL-4 production also differed between the two strains. In summary, resistant AKR mice produced more IFN-gamma and T. spiralis-specific IgG2a than susceptible B10.BR mice, which produced more IL-4, IgE, and T. spiralis-specific IgG1. Our results are consistent with differential activation of Th cell subsets in T. spiralis-infected AKR and B10.BR mice.     

Promotion of skin graft tolerance across MHC barriers by mobilization of dendritic cells in donor hemopoietic cell infusions

Flt3 ligand (FL) dramatically increases the number of immunostimulatory dendritic cells (DC) and their precursors in bone marrow (BM) and secondary lymphoid tissues. Herein we tested the ability of FL-mobilized donor hemopoietic cells to promote induction of skin graft tolerance across full MHC barriers. C57BL/10 (B10; H2(b), IE(-)) mice were given 10(8) spleen cells (SC) from normal or FL-treated, H-2-mismatched B10.D2 (H2(d), IE(+)) donors i.v. on day 0, 200 mg/kg i.p. cyclophosphamide on day 2, and 10(7) T cell-depleted BM cells from B10.D2 mice on day 3. B10.D2 skin grafting was performed on day 14. Indefinite allograft survival (100 days) was induced in recipients of FL-SC, but not in mice given normal SC. Tolerance was associated with blood macrochimerism and was confirmed by second-set skin grafting with donor skin 100 days after the first graft. In tolerant mice, peripheral donor-reactive T cells expressing TCR Vbeta11 were deleted selectively. Immunocompetence of tolerant FL-SC-treated mice was proven by rapid rejection of third-party skin grafts. To our knowledge this is the first report that mobilization of DC in donor cell infusions can be used to induce skin graft tolerance across MHC barriers, accompanied by specific deletion of donor-reactive T cells.     

Induction of permanent mixed chimerism and skin allograft tolerance across fully MHC-mismatched barriers by the additional myelosuppressive treatments in mice primed with allogeneic spleen cells followed by cyclophosphamide

A pure method of drug (cyclophosphamide plus busulfan)-induced skin allograft tolerance in mice that can regularly overcome fully H-2-mismatched barriers in mice has been established. The components of the method are i.v. administration of 1 x 108 allogeneic spleen cells on day 0, i.p. injection of 200 mg/kg CP and 25 mg/kg busulfan on day 2, and i.v. injection of T cell-depleted 1 x 107 bone marrow cells from the same donor on day 3. Recipient B10 (H-2b; IE-) mice prepared with this conditioning developed donor-specific tolerance, and long-lasting survival of skin allografts was shown in almost of the recipient mice. In the tolerant B10 mice prepared with new conditioning, stable multilineage mixed chimerism was observed permanently, and IE-reactive Vbeta11+ T cells were reduced in periphery as seen in untreated B10.D2 (H-2d; IE+) mice. The specific tolerant state was confirmed by the specific abrogation against donor Ag in the assays of CTL activity and MLR and donor-specific acceptance in the second skin grafting. These results demonstrated that the limitation of standard protocol of cyclophosphamide-induced tolerance, which have been reported by us since 1984, can be overcome by the additional treatments with the myelosuppressive drug busulfan, followed by 1 x 107 T cell-depleted bone marrow cells. To our knowledge, this is the first report to induce allograft tolerance with a short course of the Ag plus immunosuppressive drug treatment without any kind of mAbs (pure drug-induced tolerance).     

Genotypic influences on reproductive aging of inbred female mice: effects of H-2 and non-H-2 alleles

The H-2 (major histocompatibility) complex of mice influences a variety of physiologic parameters. This study describes the influences of H-2 polymorphisms and other genetic influences on age-related changes (5-20 mo) in estrous cycles and fecundity. We monitored estrous cycles of virgin or retired-breeder mice of congenic strains on the background of C57BL/10Sn (B10):B10.BR/Sg (B10.BR) and B10.RIII/Sn (B10.RIII). For another comparison, we examined the C57BL/6J (B6) strain, which has the same H-2 haplotype as the B10. Estrous cycles were categorized by length during 10 mo of observations. From 5 to 15 mo of age, B10 and B10.RIII mice displayed a preponderance of 5-day cycles, B10.BR mice displayed a preponderance of 4-day cycles, and B6 mice had diminishing numbers of 4-day cycles. Age-related acyclicity differed with strain, particularly among retired breeders; B6 mice had an earlier onset and more rapid increase of acyclicity with age than the B10 congenic mice. Litters/female, maternal age at last litter, and total pups/female differed with strain; B10.BR and B10.RIII were similar and both had greater values than B10 mice. In conclusion, reproductive senescence of female mice was influenced by genes at the H-2 locus and elsewhere.     

Differential effect of Bacillus firmus on immune response and enterocyte brush-border enzyme levels in BALB/c and B10.BR mice

A nonpathogenic bacterium of external environment possessing remarkable immunomodulatory activity, Bacillus firmus (BF) inactivated with formaldehyde, was given intragastrically to two genetically different mouse strains BALB/c (H-2d) and B10.BR/SnPh (B10.BR, H-2k) reared in conventional (CV) and B10.BR strain also in germ-free (GF) conditions. Repeated intragastric administration of BF (500 micrograms every other day over two weeks, starting at the age of 3 months) significantly enhanced intestinal IgA levels in CV BALB/c mice but did not affect intestinal IgA in CV B10.BR mice. In GF B10.BR mice, IgG levels in sera and intestinal washings increased after BF administration compared to CV B10.BR mice. In CV BALB/c mice, specific activity of enterocyte brush-border enzymes (lactase, gamma-glutamyltransferase, alkaline phosphatase) decreased after BF treatment; sucrase (sucrose alpha-glucosidase) activity was not affected. On the other hand, in B10.BR mice, specific activity of gamma-glutamyltransferase and dipeptidyl peptidase IV were higher after administration of BF in both CV and GF groups relative to untreated controls. The activities of lactase and glucoamylase (glucan 1,4-alpha-glucosidase) were significantly stimulated only in the group of GF B10.BR mice treated with formolized BF. The stimulation of immunoglobulin production after BF treatment was accompanied by changes in the levels of enterocyte brush-border enzymes; this responsiveness to BF treatment was genetically regulated.     

Specific destruction of host-reactive mature T cells of donor origin prevents graft-versus-host disease in cyclophosphamide-induced tolerant mice.

In cyclophosphamide (CP)-induced tolerance, a long lasting skin allograft tolerance was established in many H-2-identical strain combinations without graft vs host disease. Destruction of donor-reactive T cells of host origin, followed by intrathymic clonal deletion of these cells, has been revealed to be the chief mechanisms of this system. Here, we studied the fate of host-reactive populations in donor-derived T cells of C3H/He (C3H) (H-2k, Mls-1b, Mls-2a) mice rendered CP-induced tolerant to AKR/J (AKR) (H-2k, Mls-1a, Mls-2b), by assessing AKR-derived Thy-1.1+ T cells bearing TCR V beta 3 that are specifically reactive with Mls-2a-encoded Ag of the recipient C3H mice. In the AKR-derived Thy-1.1+ lymph node cells of the C3H mice that had been treated with AKR spleen cells plus CP, CD4(+)-V beta 3+ T cells were obviously decreased by day 10 after the CP treatment. At this stage, the Thy-1.1+ T cells were not detected in the C3H thymus, suggesting that the obvious decrease of CD4(+)-V beta 3+ T cells of AKR origin was not due to intrathymic clonal deletion in the recipient C3H mice. Therefore, the destruction of the host-reactive mature T cells of donor origin, as well as that of the donor-reactive mature T cells of host origin, occurred by the CP treatment at the induction phase. Furthermore, after the establishment of intrathymic mixed chimerism in the recipient C3H mice, V beta 3+ T cells were not detected among the Thy-1.1+ T cells of AKR origin in the mixed chimeric thymus, suggesting that the host-reactive immature T cells repopulated from the injected donor hematopoietic cells were clonally deleted in the recipient thymus. These two mechanisms appear to prevent graft vs host disease in CP-induced tolerance.     

Modulation of F1 cytotoxic potentials by GvHR: role and mode of action of non-MHC genes that determine the hybrid resistance to GvHR-associated suppression of F1 cytotoxic potential

The resistance of unirradiated F1 mice against graft-vs-host reaction (GvHR) induced by lymphocytes from certain parental strains is apparently a violation of the basic law in classical transplantation immunity. To explore genetic mechanisms of this peculiar phenomenon, GvHR-associated immunosuppression was examined on various kinds of F1 mice undergoing GvHR induced by parental lymphocytes. In F1 mice raised by crossing DBA/2 mice with various H-2-congeneic B10-series strains, parental lymphocytes having non-H-2 genetic background of DBA (DBA/2 and DBA/1) invariably could not induce GvHR-associated immunosuppression, irrespective of the H-2 haplotype incompatibility involved, whereas lymphocytes of the partner parental strain induced the immunosuppression. The number of the relevant loci in the DBA non-H-2 was assessed to be three recessive loci by examination of the capability to induce the GvHR-associated immunosuppression on lymphocytes from individual (B 10.D2 X DBA/2)F1 X DBA/2 backcross mice. On the other hand, in F1 mice raised by crossing C3H/He or AKR/J mice with various H-2-congeneic B10-series strains, parental lymphocytes of H-2k haplotype, irrespective of their non-H-2 haplotype, invariably could not induce the GvHR-associated immunosuppression. Furthermore, it was revealed that non-H-2 genes of parental C3H or AKR incorporated in the F1 mice determine the resistance of the F1 mice against the H-2k-induced GvHR. The results of examination of the resistance on individual (B10 X [B10.BR X C3H/He]F1) and (B10 X [B10.BR X AKR/J]F1) mice suggested that three non-H-2 loci of C3H/He or two non-2 loci of AKR/J incorporated in F1 hybrids could determine the resistance of the respective F1 mice.     

Primary in vitro cytotoxic response of F1 T lymphocytes against parental antigens.

Spleen cells from adult female (AKR/J x BALB/(c)F1 mice can respond to mitomycin C-treated spleen from AKR/J mice and can generate effector CTL in a 5-day primary in vitro culture. The response is comparable in magnitude to the response to allogeneic H-2K or H-2D antigens. The response is T cell mediated and is directed to antigen(s) present only on the parental cells. The target cell must be homozygous at H-2Kk to be lysed and H-2Dk antigens do not serve as a target in this response. Spleen cells from (B10.BR x B10.D2) hybrids that have been stimulated with AKR/J lyse B10.Br as well as AKR/J target cells. Similar H-2k/d hybrid F1 anti-H-2k parent responses are seen in certain other strain combinations. A number of possible interpretations of these responses are discussed.     

Cytotoxic T lymphocyte response to minor H-42a alloantigen in H-42b mice: clonal inactivation of the precursor cytotoxic T lymphocytes by veto-like spleen cells that express the H-42a antigen

When (B10.BR X CWB)F1 (BWF1; H-2k/b) mice carrying the H-42b allele at the minor H-42 locus were injected with H-42a C3H.SW (CSW; H-2b) or C3H (H-2k) spleen cells (SC), self-H-2Kb restricted anti-H-42a pCTL in the BWF1 recipients were primed and differentiated to anti-H-42a CTL after in vitro stimulation with (B10.BR X CSW)F1 (BSF1; H-2k/b, H-42b/a) SC. In contrast, anti-H-42a pCTL in H-42b mice were inactivated by injection with H-42-congenic H-42a SC, and stable anti-H-42a CTL tolerance was induced. Preference of H-2Kb restriction of anti-H-42a CTL was strict, and self-H-2Kb-restricted anti-H-42a CTL did not lyse target cells carrying H-42a antigen in the context of H-2Kbm1. Involvement of suppressor cells in the anti-H-42a CTL tolerance was ruled out by the present cell transfer study and the previous cell-mixing in vitro study. Notably, treatment with anti-Thy-1.2 antibody (Ab) plus complement (C) wiped out the ability of CSW SC in the priming of anti-H-42a pCTL of BWF1 mice but left that of C3H SC unaffected, and injection of the anti-Thy-1.2 Ab plus C-treated CSW SC induced anti-H-42a CTL tolerance in the BWF1 recipients. Furthermore, H-42a/b, I-Ab/bm12 [CSW X B6.CH-2bm12 (bm12)]F1 SC could not prime anti-H-42a pCTL in H-42b, I-Ab (CWB X B6)F1 recipients, whereas H-42a/b, I-Ab (CSW X B6)F1 SC primed anti-H-42a pCTL in H-42b, I-Ab/bm12 (CWB X bm12)F1 recipients. The unresponsiveness of anti-H-42a pCTL in H-42b mice to H-42-congenic H-42a SC was sometimes corrected by immunization of H-42b female mice with H-42-congenic H-42a male SC. Taking all of the results together, we propose the following. Unresponsiveness of anti-H-42a pCTL in H-42b mice to H-42-congenic H-42a SC is caused by "veto cells" contained in the antigenic H-42a SC. Anti-H-42a pCTL in the H-42b recipients directly interacting with H-42-congenic H-42a SC, which bear H-42a antigen and H-2Kb restriction element, are inactivated or vetoed.(ABSTRACT TRUNCATED AT 400 WORDS)     

AKR/J gene(s) unlinked to H-2 determines dominant inheritance of lymphocyte hyporesponsiveness to acetylcholine receptor

Mice with the H-2b major histocompatibility complex haplotype are high immune responders to nicotinic acetylcholine receptors (AChR), whereas mice with the H-2k haplotype are generally low responders. F1 progeny of C57BL/6 (H-2b) mice crossed with mice of most H-2k strains are high responders to AChR in standard conditions of testing helper T cell proliferation in vitro (4 X 10(5) lymph node cells/microwell, 1 wk after primary challenge in vivo). In contrast, the F1 progeny of AKR/J (H-2k) crossed with high responder (H-2b) strains (B6, A.BY, or C3H.SW) were all hyporesponsive to AChR when lymphocytes were tested at 4 X 10(5) cells/well. However, at a density of 1 X 10(6) or greater/well, a high level of antigen-specific responsiveness was demonstrable in the F1 hybrid lymphocytes. A shift from low to high responsiveness to AChR at high cell densities was observed also in the H-2b strain AKR.B6. Other strains previously demonstrated to be low responders to AChR did not become responsive to AChR when lymphocyte numbers were increased to 1.4 X 10(6)/well. The N2 generation yielded by backcrossing (AKR X B6)F1 mice to AKR/J were all low responders, whereas N2 progeny derived by backcrossing F1 to B6 were high or low responders in a ratio of approximately 1:1 (independent of their H-2 phenotype). Results consistent with this observation were obtained in (AKR X B6) F2 mice. These data suggest that at least one AKR/J gene outside of the H-2 complex exerts a hyporesponsive influence on the I-A-dependent helper T cell response to AChR in H-2b mice.     

Inheritance of tolerance susceptibility to human gamma-globulin in congenic mice.

The genetic control of susceptibility to tolerance induction with human gamma-globulin (HGG) was studied by using H-2 congenic mice. Strains tested that were congenic with C57BL/10Sn were completely tolerized by 1.0 mg deaggregated HGG. In contrast A/Sn mice showed full tolerance whereas A.SW mice were only intermediately tolerant. It was further shown that (B10 X SJL)F1 mice could be rendered tolerant but (B10.S X SJL)F1 mice could not. These data indicate a role for H-2 linked genes in control of tolerance susceptibility. Results obtained with the progeny of (B10.S X SJL)F1 backcrossed to B10.S indicate that two non-H-2 linked genes are involved in control of tolerance induction. Preliminary mapping studies show the H-2 gene located to the left of the IC subregion. These results confirm our previous finding that both H-2 and non-H-2 genes control susceptibility of adult mice to tolerance induction with HGG.     

Cytotoxic T-lymphocyte tolerance to minor H-43a alloantigen is induced exclusively in the context of the self major histocompatibility complex class I H-2Kb molecules

We elucidated previously that cytotoxic T lymphocyte precursors (CTLp) against H-43a allo-antigen, which we had discovered as a new mouse minor H antigen, were primed in H-43b mice only in the context of self H-2Kb restriction element, and that anti-H-43a CTLp tolerance was induced in H-43b mice by injection with H-43a spleen cells (SC) from H-43 congenic mice, i.e., under the condition of disparity at only the H-43 locus. The present study attempted to determine whether the H-2Kb restriction element for anti-H-43a CTLp priming is also implicated in the induction of anti-H-43a CTLp tolerance. For this purpose, we used a newly established H-43b C3W (H-2k) strain which is H-43 congenic to H-43a C3H/HeN. When (C3W X B10.MBR)F1 (H-43b, H-2Kk/b, Ik/k, Dk/q) mice were injected with H-43a-bearing (C3H/HeN X B10.AKM)F1 (H-43a/b;H-2Kk/k,Ik/k,Dk/q)SC, their selfH-2Kb-restricted anti-H-43a CTLp were were primed (cross-priming). By contrast, injection of H-43a-bearing (C3H/HeN X B10.MBR)F1 (H-43a/b; H-2Kk/b,Ik/k, Dk/q)SC, which differ from (C3H/HeN x B10.AKM) F1 SC solely at H-2K and possess H-2Kb molecules, did not prime but specifically inactivated the anti-H-43a CTLp of (C3W x B10.MBR)F1 mice. These results indicate clearly that anti-H-43a CTLp tolerance is induced exclusively in the context of the H-2Kb element expressed on the antigenic H-43a SC.     

Genetic differences in BCG-induced resistance to Schistosoma mansoni are not controlled by genes within the major histocompatibility complex of the mouse.

Induction of nonspecific resistance to Schistosoma mansoni infection after the i.v. injection of viable BCG was investigated in outbred mice and a panel of inbred and H-2 congenic strains. Significant protection was induced in CF1, A/J, C57BL/6, C57BL/10, DBA/2, C57BR, and SJL mice. BALB/c mice were not protected whereas CBA and C3H mice expressed intermediate degrees of protection. Expression of the protective phenomenon is not controlled by genes within the MHC as shown by the marked differences in response between BALB/c and DBA/2 (H-2d) as well as between C57BR and C3H (H-2k) mice. H-2 congenic strains with C57BL/10 background (B10.A and B10.D2) were high responders. BALB.B10 mice carrying the high responder (B10) MHC on the nonresponder (BALB/c) background were not protected. The degree of splenic hypertrophy did not correlate with the expression of nonspecific resistance. These results demonstrate that, in addition to controlling specific immune responses, genetic differences influence the nonspecific protective phenomena related to BCG administration as well.     

Ia Restriction Specificity of KLH-Specific T Cells from Allogeneic Bone Marrow Chimeras Is Influenced by Histocompatibility at the H-2 and Minor Histocompatibility Loci

Ia restriction specificity involved in T cell proliferative responses to keyhole limpet hemocyanin (KLH) has been analyzed using a variety of allogeneic bone marrow chimeras. The chimeric mice were prepared by reconstituting irradiated AKR, SJL, B10.BR and B10.A(4R) mice with bone marrow cells from B10 mice. When such chimeric mice had first been primed with KLH in complete Freund's adjuvant (CFA), T cells from H-2 incompatible fully allogeneic chimeras showed significantly higher responses to KLH in the presence of antigen-presenting cells (APC) of donor strain (B10) than APC of recipient strain. However, in H-2 subregion compatible chimeras, [B10→B10.A(4R)], which were matched at the H-2D locus and at minor histocompatible loci, the T cells could mount vigorous responses to KLH with antigen-presenting cells (APC) of either donor or recipient type. The same results were obtained as well with chimeras that had been thymectomized after full reconstitution of lymphoid tissues by donor-derived cells. A considerable proportion of KLH-specific T cell hybridomas established from [B10→B10.A(4R)] chimeras exhibited both I-A^b and I-A^k restriction specificities. The present findings indicate that the bias to donor Ia type of antigen specific T cells is determined by donor-derived APC present in the extrathymic environment but that cross-reactivity to the recipient Ia is influenced to some degree by histocompatibility between donor and recipient mice, even though the histocompatible H-2D locus and minor histocompatibility loci seem not to be directly involved in the I-A restricted responses studied herein.     

Neonatal tolerance induction in the thymus to MHC-class II-associated antigens. I. Preferential induction of tolerance to Mls antigens and resistance to allo-MHC antigens

Neonatal tolerance inducibility of self-major histocompatibility complex (MHC)-class II-associated antigens was compared with that of allo-class II antigens. BALB/c (H-2d, Mlsb) mice, less than 24 hr after birth, were intravenously injected with bone marrow cells of either (BALB/c X DBA/2)F1 (H-2d, Mlsb/a, semiallogeneic at the Mls locus) or (BALB/c X B10.BR)F1 (H-2d/k, Mlsb; semiallogeneic at the MHC), as antigens. The mice were tested for in vivo immune activity of class II-reactive T cells by means of the popliteal lymph node-swelling assay. They developed tolerance, irrespective of type of antigens, showing profoundly suppressed host-versus-graft reaction, and those tolerized to the allo-MHC antigens accepted skin grafts of the corresponding allogeneic mice. In the thymus and spleen of the Mls-tolerant mice, antigen-specific class II-reactive T-cell activity was completely abolished, without the apparent involvement of suppressor cells. In contrast, the activity in allo-MHC-tolerant mice was not reduced in either thymus or peripheral lymphoid organs, suggesting that systemic hyporesponsiveness is attributable to reversible suppression of immune competent cells. The resistance for cell-level tolerance induction to allo-class II antigens may not be ascribed to the active participation of allo-MHC antigens in prevention of or in escape from tolerance induction or both, since an injection of bone marrow cells of both Mls and H-2-semiallogeneic (DBA/2 X B10.BR)F1 (H-2d/k, Mlsa/b) mice could induce tolerance to Mlsa-H-2d antigens in newborn thymus cells.     

Sensitivity to corticosterone-induced cleft palate is not associated with H-2

The frequency of cleft palate (CP) and corticosterone levels in maternal plasma and amniotic fluid were determined in pregnant C57BL/10 (H-2b) and congenic B10.A (H-2a) mice after the ip injection of repository ACTH, corticosterone acetate, or desoxycorticosterone acetate (DOCA) on the 11th through 14th day of gestation. It was found that ACTH (a) induces CP in B10.A but not C57BL/10 mice, (b) induces CP in B10.A mice at about the same frequency noted when diluent alone is injected, and (c) produces an elevation in maternal plasma corticosterone levels 1.5- to 2.0-fold lower and amniotic fluid levels 3- to 5-fold lower than those found after the injection of 5 mg corticosterone acetate, a dose which induces a comparable frequency of CP in B10.A mice. The injection of 5 mg corticosterone acetate produced CP frequencies in C57BL/10 and B10.A mice of 4.9 and 3.3%, respectively, and increasing the dose to 9.2 mg resulted in significant increases in CP to 23.8 and 24.7%, respectively. DOCA at two dose levels induced CP in B10.A fetuses at about the frequency noted when diluent alone has been given. These findings show that susceptibility to corticosterone induced CP is not associated with the major histocompatibility complex of the mouse, H-2, as is the case with glucocorticoids (e.g., cortisone, dexamethasone), and they raise the possibility that factors other than or in addition to corticosterone may be involved in spontaneous or ACTH- or stress-induced CP.